/********************************************************************\
Name: frontend.c
Created by: Jimmy Ngai
Date: May 9, 2010
Contents: Experiment specific readout code (user part) of
Midas frontend.
Supported VME modules:
CAEN V1718 VME-USB Bridge
CAEN V792N 16 CH QDC
$Id: $
\********************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include "midas.h"
#include "mcstd.h"
#include "mvmestd.h"
#include "experim.h"
#include "vme/v792n.h"
/* make frontend functions callable from the C framework */
#ifdef __cplusplus
extern "C" {
#endif
/*-- Globals -------------------------------------------------------*/
/* The frontend name (client name) as seen by other MIDAS clients */
char *frontend_name = "Frontend";
/* The frontend file name, don't change it */
char *frontend_file_name = __FILE__;
/* frontend_loop is called periodically if this variable is TRUE */
BOOL frontend_call_loop = FALSE;
/* a frontend status page is displayed with this frequency in ms */
INT display_period = 3000;
/* maximum event size produced by this frontend */
INT max_event_size = 10000;
/* maximum event size for fragmented events (EQ_FRAGMENTED) */
INT max_event_size_frag = 5 * 1024 * 1024;
/* buffer size to hold events */
INT event_buffer_size = 10 * 10000;
/* number of channels */
#define N_ADC 16
/* VME hardware */
MVME_INTERFACE *myvme;
/* VME base address */
DWORD V1718_BASE = 0x12000000;
DWORD V792N_BASE = 0x32100000;
/*-- Function declarations -----------------------------------------*/
INT frontend_init();
INT frontend_exit();
INT begin_of_run(INT run_number, char *error);
INT end_of_run(INT run_number, char *error);
INT pause_run(INT run_number, char *error);
INT resume_run(INT run_number, char *error);
INT frontend_loop();
INT read_trigger_event(char *pevent, INT off);
/*-- Equipment list ------------------------------------------------*/
#undef USE_INT
EQUIPMENT equipment[] = {
{"Trigger", /* equipment name */
{1, 0, /* event ID, trigger mask */
"SYSTEM", /* event buffer */
#ifdef USE_INT
EQ_INTERRUPT, /* equipment type */
#else
EQ_POLLED, /* equipment type */
#endif
LAM_SOURCE(CRATE, LAM_STATION(SLOT_ADC)), /* event source */
"MIDAS", /* format */
TRUE, /* enabled */
RO_RUNNING | /* read only when running */
RO_ODB, /* and update ODB */
500, /* poll for 500ms */
0, /* stop run after this event limit */
0, /* number of sub events */
0, /* don't log history */
"", "", "",},
read_trigger_event, /* readout routine */
},
{""}
};
#ifdef __cplusplus
}
#endif
/********************************************************************\
Callback routines for system transitions
These routines are called whenever a system transition like start/
stop of a run occurs. The routines are called on the following
occations:
frontend_init: When the frontend program is started. This routine
should initialize the hardware.
frontend_exit: When the frontend program is shut down. Can be used
to releas any locked resources like memory, commu-
nications ports etc.
begin_of_run: When a new run is started. Clear scalers, open
rungates, etc.
end_of_run: Called on a request to stop a run. Can send
end-of-run event and close run gates.
pause_run: When a run is paused. Should disable trigger events.
resume_run: When a run is resumed. Should enable trigger events.
\********************************************************************/
INT init_vme_modules()
{
/* default settings */
v792n_SoftReset(myvme, V792N_BASE);
v792n_Setup(myvme, V792N_BASE, 2);
// v792n_Status(myvme, V792N_BASE);
return SUCCESS;
}
/*-- Frontend Init -------------------------------------------------*/
INT frontend_init()
{
INT status;
/* open VME interface */
status = mvme_open(&myvme, 0);
/* set am to A32 non-privileged Data */
mvme_set_am(myvme, MVME_AM_A32_ND);
/* initialize all VME modules */
init_vme_modules();
v792n_OfflineSet(myvme, V792N_BASE);
v792n_DataClear(myvme, V792N_BASE);
/* print message and return FE_ERR_HW if frontend should not be started */
if (status != MVME_SUCCESS) {
cm_msg(MERROR, "frontend_init", "VME interface could not be opened.");
return FE_ERR_HW;
}
return SUCCESS;
}
/*-- Frontend Exit -------------------------------------------------*/
INT frontend_exit()
{
/* close VME interface */
mvme_close(myvme);
return SUCCESS;
}
/*-- Begin of Run --------------------------------------------------*/
INT begin_of_run(INT run_number, char *error)
{
/* Initialize all VME modules */
// init_vme_modules();
v792n_DataClear(myvme, V792N_BASE);
v792n_OnlineSet(myvme, V792N_BASE);
return SUCCESS;
}
/*-- End of Run ----------------------------------------------------*/
INT end_of_run(INT run_number, char *error)
{
v792n_OfflineSet(myvme, V792N_BASE);
v792n_DataClear(myvme, V792N_BASE);
return SUCCESS;
}
/*-- Pause Run -----------------------------------------------------*/
INT pause_run(INT run_number, char *error)
{
v792n_OfflineSet(myvme, V792N_BASE);
return SUCCESS;
}
/*-- Resuem Run ----------------------------------------------------*/
INT resume_run(INT run_number, char *error)
{
v792n_OnlineSet(myvme, V792N_BASE);
return SUCCESS;
}
/*-- Frontend Loop -------------------------------------------------*/
INT frontend_loop()
{
/* if frontend_call_loop is true, this routine gets called when
the frontend is idle or once between every event */
return SUCCESS;
}
/*------------------------------------------------------------------*/
/********************************************************************\
Readout routines for different events
\********************************************************************/
/*-- Trigger event routines ----------------------------------------*/
INT poll_event(INT source, INT count, BOOL test)
/* Polling routine for events. Returns TRUE if event
is available. If test equals TRUE, don't return. The test
flag is used to time the polling */
{
INT i;
DWORD lam = 0;
for (i = 0; i < count; i++) {
lam = v792n_DataReady(myvme, V792N_BASE);
if (lam)
if (!test)
return lam;
}
return 0;
}
/*-- Interrupt configuration ---------------------------------------*/
INT interrupt_configure(INT cmd, INT source, POINTER_T adr)
{
switch (cmd) {
case CMD_INTERRUPT_ENABLE:
break;
case CMD_INTERRUPT_DISABLE:
break;
case CMD_INTERRUPT_ATTACH:
break;
case CMD_INTERRUPT_DETACH:
break;
}
return SUCCESS;
}
/*-- Event readout -------------------------------------------------*/
INT read_v792n(INT base, const char *bk_name, char *pevent, INT n_chn)
{
INT i;
INT nentry = 0, counter;
DWORD data[V792N_MAX_CHANNELS+2];
WORD *pdata;
/* event counter */
// v792n_EvtCntRead(myvme, base, &counter);
/* read event */
v792n_EventRead(myvme, base, data, &nentry);
/* clear ADC */
// v792n_DataClear(myvme, base);
/* create ADC bank */
bk_create(pevent, bk_name, TID_WORD, &pdata);
... 29 more lines ...
|
/*********************************************************************
Name: v1718.h
Created by: Jimmy Ngai
Contents: V1718 VME-USB2.0 bridge include
$Id: $
*********************************************************************/
#ifndef V1718_INCLUDE_H
#define V1718_INCLUDE_H
#include <stdio.h>
#include <string.h>
#include "mvmestd.h"
#ifdef __cplusplus
extern "C" {
#endif
#define V1718_STATUS_RO (DWORD) (0x0000)
#define V1718_VME_CTRL_RW (DWORD) (0x0001)
#define V1718_FW_REV_RO (DWORD) (0x0002)
#define V1718_FW_DWNLD_RW (DWORD) (0x0003)
#define V1718_FL_ENA_RW (DWORD) (0x0004)
#define V1718_IRQ_STAT_RO (DWORD) (0x0005)
#define V1718_IN_REG_RW (DWORD) (0x0008)
#define V1718_OUT_REG_S_RW (DWORD) (0x000A)
#define V1718_IN_MUX_S_RW (DWORD) (0x000B)
#define V1718_OUT_MUX_S_RW (DWORD) (0x000C)
#define V1718_LED_POL_S_RW (DWORD) (0x000D)
#define V1718_OUT_REG_C_WO (DWORD) (0x0010)
#define V1718_IN_MUX_C_WO (DWORD) (0x0011)
#define V1718_OUT_MAX_C_WO (DWORD) (0x0012)
#define V1718_LED_POL_C_WO (DWORD) (0x0013)
#define V1718_PULSEA_0_RW (DWORD) (0x0016)
#define V1718_PULSEA_1_RW (DWORD) (0x0017)
#define V1718_PULSEB_0_RW (DWORD) (0x0019)
#define V1718_PULSEB_1_RW (DWORD) (0x001A)
#define V1718_SCALER0_RW (DWORD) (0x001C)
#define V1718_SCALER1_RO (DWORD) (0x001D)
#define V1718_DISP_ADL_RO (DWORD) (0x0020)
#define V1718_DISP_ADH_RO (DWORD) (0x0021)
#define V1718_DISP_DTL_RO (DWORD) (0x0022)
#define V1718_DISP_DTH_RO (DWORD) (0x0023)
#define V1718_DISP_PC1_RO (DWORD) (0x0024)
#define V1718_DISP_PC2_RO (DWORD) (0x0025)
#define V1718_LM_ADL_RW (DWORD) (0x0028)
#define V1718_LM_ADH_RW (DWORD) (0x0029)
#define V1718_LM_C_RW (DWORD) (0x002C)
WORD v1718_Read16(MVME_INTERFACE *mvme, DWORD base, int offset);
void v1718_Write16(MVME_INTERFACE *mvme, DWORD base, int offset, WORD value);
DWORD v1718_Read32(MVME_INTERFACE *mvme, DWORD base, int offset);
void v1718_Write32(MVME_INTERFACE *mvme, DWORD base, int offset, DWORD value);
void v1718_MultiRead(MVME_INTERFACE *mvme, DWORD *addrs, DWORD *value, int ncycle, int *am, int *dmode);
void v1718_MultiWrite(MVME_INTERFACE *mvme, DWORD *addrs, DWORD *value, int ncycle, int *am, int *dmode);
void v1718_MultiRead16(MVME_INTERFACE *mvme, DWORD *addrs, WORD *value, int ncycle);
void v1718_MultiWrite16(MVME_INTERFACE *mvme, DWORD *addrs, WORD *value, int ncycle);
void v1718_MultiRead32(MVME_INTERFACE *mvme, DWORD *addrs, DWORD *value, int ncycle);
void v1718_MultiWrite32(MVME_INTERFACE *mvme, DWORD *addrs, DWORD *value, int ncycle);
void v1718_PulserConfSet(MVME_INTERFACE *mvme, WORD pulser, DWORD period, DWORD width, WORD pulseNo);
void v1718_PulserStart(MVME_INTERFACE *mvme, WORD pulser);
void v1718_PulserStop(MVME_INTERFACE *mvme, WORD pulser);
enum v1718_PulserSelect {
v1718_pulserA=0x0,
v1718_pulserB=0x1,
};
#ifdef __cplusplus
}
#endif
#endif // V1718_INCLUDE_H
/* emacs
* Local Variables:
* mode:C
* mode:font-lock
* tab-width: 8
* c-basic-offset: 2
* End:
*/
|
/********************************************************************
Name: v1718.c
Created by: Jimmy Ngai
Contents: Midas VME standard (MVMESTD) layer for CAEN V1718
VME-USB2.0 Bridge using CAENVMElib Linux library
$Id: $
\********************************************************************/
#ifdef __linux__
#ifndef OS_LINUX
#define OS_LINUX
#endif
#endif
#ifdef OS_LINUX
#define _GNU_SOURCE
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "CAENVMElib.h"
#endif // OS_LINUX
#include "v1718.h"
/*------------------------------------------------------------------*/
/********************************************************************\
MIDAS VME standard (MVMESTD) functions
\********************************************************************/
int mvme_open(MVME_INTERFACE **vme, int idx)
{
*vme = (MVME_INTERFACE *) malloc(sizeof(MVME_INTERFACE));
if (*vme == NULL)
return MVME_NO_MEM;
memset(*vme, 0, sizeof(MVME_INTERFACE));
/* open VME */
if (CAENVME_Init(cvV1718, 0, idx, &(*vme)->handle) != cvSuccess)
return MVME_NO_INTERFACE;
/* default values */
(*vme)->am = MVME_AM_DEFAULT;
(*vme)->dmode = MVME_DMODE_D32;
(*vme)->blt_mode = MVME_BLT_NONE;
(*vme)->table = NULL; // not used
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_close(MVME_INTERFACE *vme)
{
CAENVME_End(vme->handle);
free(vme);
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_sysreset(MVME_INTERFACE *vme)
{
CAENVME_SystemReset(vme->handle);
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_write(MVME_INTERFACE *vme, mvme_addr_t vme_addr, void *src, mvme_size_t n_bytes)
{
mvme_size_t i;
int status=0, n;
int hvme;
hvme = vme->handle;
n = 0;
/* D8 */
if (vme->dmode == MVME_DMODE_D8) {
for (i=0 ; i<n_bytes ; i++)
status = CAENVME_WriteCycle(hvme, vme_addr, src+i, vme->am, cvD8);
n = n_bytes;
/* D16 */
} else if (vme->dmode == MVME_DMODE_D16) {
/* normal I/O */
if (vme->blt_mode == MVME_BLT_NONE) {
for (i=0 ; i<(n_bytes>>1) ; i++)
status = CAENVME_WriteCycle(hvme, vme_addr, src+(i<<1), vme->am, cvD16);
n = n_bytes;
/* FIFO BLT */
} else if ((vme->blt_mode == MVME_BLT_BLT32FIFO) || (vme->blt_mode == MVME_BLT_MBLT64FIFO))
status = CAENVME_FIFOBLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, cvD16, &n);
/* BLT */
else
status = CAENVME_BLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, cvD16, &n);
/* D32 */
} else if (vme->dmode == MVME_DMODE_D32) {
/* normal I/O */
if (vme->blt_mode == MVME_BLT_NONE) {
for (i=0 ; i<(n_bytes>>2) ; i++)
status = CAENVME_WriteCycle(hvme, vme_addr, src+(i<<2), vme->am, cvD32);
n = n_bytes;
/* FIFO BLT */
} else if (vme->blt_mode == MVME_BLT_BLT32FIFO)
status = CAENVME_FIFOBLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, cvD32, &n);
/* BLT */
else
status = CAENVME_BLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, cvD32, &n);
/* D64 */
} else if (vme->dmode == MVME_DMODE_D64) {
/* FIFO MBLT */
if (vme->blt_mode == MVME_BLT_MBLT64FIFO)
status = CAENVME_FIFOMBLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, &n);
/* MBLT */
else
status = CAENVME_MBLTWriteCycle(hvme, vme_addr, src, n_bytes, vme->am, &n);
}
if (status != cvSuccess)
n = 0;
return n;
}
/*------------------------------------------------------------------*/
int mvme_write_value(MVME_INTERFACE *vme, mvme_addr_t vme_addr, unsigned int value)
{
int status=0, n;
int hvme;
hvme = vme->handle;
if (vme->dmode == MVME_DMODE_D8)
n = 1;
else if (vme->dmode == MVME_DMODE_D16)
n = 2;
else
n = 4;
/* D8 */
if (vme->dmode == MVME_DMODE_D8)
status = CAENVME_WriteCycle(hvme, vme_addr, &value, vme->am, cvD8);
/* D16 */
else if (vme->dmode == MVME_DMODE_D16)
status = CAENVME_WriteCycle(hvme, vme_addr, &value, vme->am, cvD16);
/* D32 */
else if (vme->dmode == MVME_DMODE_D32)
status = CAENVME_WriteCycle(hvme, vme_addr, &value, vme->am, cvD32);
if (status != cvSuccess)
n = 0;
return n;
}
/*------------------------------------------------------------------*/
int mvme_read(MVME_INTERFACE *vme, void *dst, mvme_addr_t vme_addr, mvme_size_t n_bytes)
{
mvme_size_t i;
int status=0, n;
int hvme;
hvme = vme->handle;
n = 0;
/* D8 */
if ((vme->dmode == MVME_DMODE_D8) || (vme->blt_mode == MVME_BLT_NONE)) {
for (i=0 ; i<n_bytes ; i++)
status = CAENVME_ReadCycle(hvme, vme_addr, dst+i, vme->am, cvD8);
n = n_bytes;
/* D16 */
} else if (vme->dmode == MVME_DMODE_D16) {
/* normal I/O */
if (vme->blt_mode == MVME_BLT_NONE) {
for (i=0 ; i<(n_bytes>>1) ; i++)
status = CAENVME_ReadCycle(hvme, vme_addr, dst+(i<<1), vme->am, cvD16);
n = n_bytes;
/* FIFO BLT */
} else if ((vme->blt_mode == MVME_BLT_BLT32FIFO) || (vme->blt_mode == MVME_BLT_MBLT64FIFO))
status = CAENVME_FIFOBLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, cvD16, &n);
/* BLT */
else
status = CAENVME_BLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, cvD16, &n);
/* D32 */
} else if (vme->dmode == MVME_DMODE_D32) {
/* normal I/O */
if (vme->blt_mode == MVME_BLT_NONE) {
for (i=0 ; i<(n_bytes>>2) ; i++)
status = CAENVME_ReadCycle(hvme, vme_addr, dst+(i<<2), vme->am, cvD32);
n = n_bytes;
/* FIFO BLT */
} else if (vme->blt_mode == MVME_BLT_BLT32FIFO)
status = CAENVME_FIFOBLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, cvD32, &n);
/* BLT */
else
status = CAENVME_BLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, cvD32, &n);
/* D64 */
} else if (vme->dmode == MVME_DMODE_D64) {
/* FIFO MBLT */
if (vme->blt_mode == MVME_BLT_MBLT64FIFO)
status = CAENVME_FIFOMBLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, &n);
/* MBLT */
else
status = CAENVME_MBLTReadCycle(hvme, vme_addr, dst, n_bytes, vme->am, &n);
}
if ((status != cvSuccess) && (status != cvBusError))
n = 0;
return n;
}
/*------------------------------------------------------------------*/
unsigned int mvme_read_value(MVME_INTERFACE *vme, mvme_addr_t vme_addr)
{
unsigned int data;
int status=0;
int hvme;
hvme = vme->handle;
data = 0;
/* D8 */
if (vme->dmode == MVME_DMODE_D8)
status = CAENVME_ReadCycle(hvme, vme_addr, &data, vme->am, cvD8);
/* D16 */
else if (vme->dmode == MVME_DMODE_D16)
status = CAENVME_ReadCycle(hvme, vme_addr, &data, vme->am, cvD16);
/* D32 */
else if (vme->dmode == MVME_DMODE_D32)
status = CAENVME_ReadCycle(hvme, vme_addr, &data, vme->am, cvD32);
return data;
}
/*------------------------------------------------------------------*/
int mvme_set_am(MVME_INTERFACE *vme, int am)
{
vme->am = am;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_get_am(MVME_INTERFACE *vme, int *am)
{
*am = vme->am;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_set_dmode(MVME_INTERFACE *vme, int dmode)
{
vme->dmode = dmode;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_get_dmode(MVME_INTERFACE *vme, int *dmode)
{
*dmode = vme->dmode;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_set_blt(MVME_INTERFACE *vme, int mode)
{
vme->blt_mode = mode;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
int mvme_get_blt(MVME_INTERFACE *vme, int *mode)
{
*mode = vme->blt_mode;
return MVME_SUCCESS;
}
/*------------------------------------------------------------------*/
... 326 more lines ...
|
/*********************************************************************
Name: v792n.h
Created by: Jimmy Ngai
Contents: V792N 16ch. QDC include
Based on v792.h by Pierre-Andre Amaudruz
$Id: $
*********************************************************************/
#ifndef V792N_INCLUDE_H
#define V792N_INCLUDE_H
#include <stdio.h>
#include <string.h>
#include "mvmestd.h"
#ifdef __cplusplus
extern "C" {
#endif
#define V792N_MAX_CHANNELS (DWORD) 16
#define V792N_REG_BASE (DWORD) (0x1000)
#define V792N_FIRM_REV (DWORD) (0x1000)
#define V792N_GEO_ADDR_RW (DWORD) (0x1002)
#define V792N_MCST_CBLT_RW (DWORD) (0x1004)
#define V792N_BIT_SET1_RW (DWORD) (0x1006)
#define V792N_BIT_CLEAR1_WO (DWORD) (0x1008)
#define V792N_SOFT_RESET (DWORD) (0x1<<7)
#define V792N_INT_LEVEL_WO (DWORD) (0x100A)
#define V792N_INT_VECTOR_WO (DWORD) (0x100C)
#define V792N_CSR1_RO (DWORD) (0x100E)
#define V792N_CR1_RW (DWORD) (0x1010)
#define V792N_ADER_H_RW (DWORD) (0x1012)
#define V792N_ADER_L_RW (DWORD) (0x1014)
#define V792N_SINGLE_RST_WO (DWORD) (0x1016)
#define V792N_MCST_CBLT_CTRL_RW (DWORD) (0x101A)
#define V792N_EVTRIG_REG_RW (DWORD) (0x1020)
#define V792N_CSR2_RO (DWORD) (0x1022)
#define V792N_EVT_CNT_L_RO (DWORD) (0x1024)
#define V792N_EVT_CNT_H_RO (DWORD) (0x1026)
#define V792N_INCR_EVT_WO (DWORD) (0x1028)
#define V792N_INCR_OFFSET_WO (DWORD) (0x102A)
#define V792N_LD_TEST_RW (DWORD) (0x102C)
#define V792N_DELAY_CLEAR_RW (DWORD) (0x102E)
#define V792N_FCLR_WIN_RW (DWORD) (0x102E)
#define V792N_BIT_SET2_RW (DWORD) (0x1032)
#define V792N_BIT_CLEAR2_WO (DWORD) (0x1034)
#define V792N_W_MEM_TEST_WO (DWORD) (0x1036)
#define V792N_MEM_TEST_WORD_H_WO (DWORD) (0x1038)
#define V792N_MEM_TEST_WORD_L_WO (DWORD) (0x103A)
#define V792N_CRATE_SEL_RW (DWORD) (0x103C)
#define V792N_TEST_EVENT_WO (DWORD) (0x103E)
#define V792N_EVT_CNT_RST_WO (DWORD) (0x1040)
#define V792N_IPED_RW (DWORD) (0x1060)
#define V792N_R_MEM_TEST_WO (DWORD) (0x1064)
#define V792N_SWCOMM_WO (DWORD) (0x1068)
#define V792N_SLIDECONST_RW (DWORD) (0x106A)
#define V792N_AAD_RO (DWORD) (0x1070)
#define V792N_BAD_RO (DWORD) (0x1072)
#define V792N_THRES_BASE (DWORD) (0x1080)
WORD v792n_Read16(MVME_INTERFACE *mvme, DWORD base, int offset);
void v792n_Write16(MVME_INTERFACE *mvme, DWORD base, int offset, WORD value);
DWORD v792n_Read32(MVME_INTERFACE *mvme, DWORD base, int offset);
void v792n_Write32(MVME_INTERFACE *mvme, DWORD base, int offset, DWORD value);
int v792n_DataReady(MVME_INTERFACE *mvme, DWORD base);
int v792n_isEvtReady(MVME_INTERFACE *mvme, DWORD base);
int v792n_isBusy(MVME_INTERFACE *mvme, DWORD base);
int v792n_EventRead(MVME_INTERFACE *mvme, DWORD base, DWORD *pdest, int *nentry);
int v792n_DataRead(MVME_INTERFACE *mvme, DWORD base, DWORD *pdest, int nentry);
void v792n_DataClear(MVME_INTERFACE *mvme, DWORD base);
void v792n_EvtCntRead(MVME_INTERFACE *mvme, DWORD base, DWORD *evtcnt);
void v792n_EvtCntReset(MVME_INTERFACE *mvme, DWORD base);
void v792n_IntSet(MVME_INTERFACE *mvme, DWORD base, int level, int vector);
void v792n_IntEnable(MVME_INTERFACE *mvme, DWORD base, int level);
void v792n_IntDisable(MVME_INTERFACE *mvme, DWORD base);
void v792n_EvtTriggerSet(MVME_INTERFACE *mvme, DWORD base, int count);
void v792n_SingleShotReset(MVME_INTERFACE *mvme, DWORD base);
void v792n_SoftReset(MVME_INTERFACE *mvme, DWORD base);
void v792n_Trigger(MVME_INTERFACE *mvme, DWORD base);
int v792n_ThresholdRead(MVME_INTERFACE *mvme, DWORD base, WORD *threshold);
int v792n_ThresholdWrite(MVME_INTERFACE *mvme, DWORD base, WORD *threshold);
int v792n_CSR1Read(MVME_INTERFACE *mvme, DWORD base);
int v792n_CSR2Read(MVME_INTERFACE *mvme, DWORD base);
int v792n_BitSet2Read(MVME_INTERFACE *mvme, DWORD base);
void v792n_BitSet2Set(MVME_INTERFACE *mvme, DWORD base, WORD pat);
void v792n_BitSet2Clear(MVME_INTERFACE *mvme, DWORD base, WORD pat);
WORD v792n_ControlRegister1Read(MVME_INTERFACE *mvme, DWORD base);
void v792n_ControlRegister1Write(MVME_INTERFACE *mvme, DWORD base, WORD pat);
void v792n_OnlineSet(MVME_INTERFACE *mvme, DWORD base);
void v792n_OfflineSet(MVME_INTERFACE *mvme, DWORD base);
void v792n_BlkEndEnable(MVME_INTERFACE *mvme, DWORD base);
void v792n_OverRangeEnable(MVME_INTERFACE *mvme, DWORD base);
void v792n_OverRangeDisable(MVME_INTERFACE *mvme, DWORD base);
void v792n_LowThEnable(MVME_INTERFACE *mvme, DWORD base);
void v792n_LowThDisable(MVME_INTERFACE *mvme, DWORD base);
void v792n_EmptyEnable(MVME_INTERFACE *mvme, DWORD base);
void v792n_CrateSet(MVME_INTERFACE *mvme, DWORD base, DWORD *evtcnt);
void v792n_DelayClearSet(MVME_INTERFACE *mvme, DWORD base, int delay);
int v792n_Setup(MVME_INTERFACE *mvme, DWORD base, int mode);
void v792n_Status(MVME_INTERFACE *mvme, DWORD base);
int v792n_isPresent(MVME_INTERFACE *mvme, DWORD base);
enum v792n_DataType {
v792n_typeMeasurement=0,
v792n_typeHeader =2,
v792n_typeFooter =4,
v792n_typeFiller =6
};
typedef union {
DWORD raw;
struct v792n_Entry {
unsigned adc:12; // bit0 here
unsigned ov:1;
unsigned un:1;
unsigned _pad_1:3;
unsigned channel:4;
unsigned _pad_2:3;
unsigned type:3;
unsigned geo:5;
} data ;
struct v792n_Header {
unsigned _pad_1:8; // bit0 here
unsigned cnt:6;
unsigned _pad_2:2;
unsigned crate:8;
unsigned type:3;
unsigned geo:5;
} header;
struct v792n_Footer {
unsigned evtCnt:24; // bit0 here
unsigned type:3;
unsigned geo:5;
} footer;
} v792n_Data;
typedef union {
DWORD raw;
struct {
unsigned DataReady:1; // bit0 here
unsigned GlobalDataReady:1;
unsigned Busy:1;
unsigned GlobalBusy:1;
unsigned Amnesia:1;
unsigned Purge:1;
unsigned TermOn:1;
unsigned TermOff:1;
unsigned EventReady:1; //bit 8 here
};
} v792n_StatusRegister1;
typedef union {
DWORD raw;
struct {
unsigned _pad_1:1; // bit0 here
unsigned BufferEmpty:1;
unsigned BufferFull:1;
unsigned _pad_2:1;
unsigned PB:4;
//unsigned DSEL0:1;
//unsigned DSEL1:1;
//unsigned CSEL0:1;
//unsigned CSEL1:1;
};
} v792n_StatusRegister2;
typedef union {
DWORD raw;
struct {
unsigned _pad_1:2;
unsigned BlkEnd:1;
unsigned _pad_2:1;
unsigned ProgReset:1;
unsigned BErr:1;
unsigned Align64:1;
};
} v792n_ControlRegister1;
typedef union {
DWORD raw;
struct {
unsigned MemTest:1;
unsigned OffLine:1;
unsigned ClearData:1;
unsigned OverRange:1;
unsigned LowThresh:1;
unsigned _pad_1:1;//bit5
unsigned TestAcq:1;
unsigned SLDEnable:1;
unsigned StepTH:1;
unsigned _pad_2:2;//bits 9-10
unsigned AutoIncr:1;
unsigned EmptyProg:1;
unsigned SlideSubEnable:1;
unsigned AllTrg:1;
};
} v792n_BitSet2Register;
void v792n_printEntry(const v792n_Data* v);
#ifdef __cplusplus
}
#endif
#endif // V792N_INCLUDE_H
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